DE25071C - Innovation in globes - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

CLASS 42: Instruments.

ALEXANDER BRIX in FRANKFURT a. M. Innovation in Globes.

Patented in the German Empire on April 24, 1883.

The aim of the innovation is to determine the exact time of sunrise or Downfall, so the Start resp. the end of the day for every point on earth, as well as for every day of the year to be able to determine easily and comfortably.

The openwork ring R is firmly screwed onto the foot F, i.e. immovable. The Fufsi ⁷ is hollow on the inside and is in. the vertical axis A is mounted on the same. With it the disk S, the inclined arm H and the axis α are firmly connected, so that these parts form a coherent whole, Fig. 2.

The globe G can be easily rotated about the axis α. At the lower end of the axis a, where it is connected to the arm H , the equatorial ring r is rotatably attached by means of the struts s. This equatorial ring has the recesses D, Fig. 5, into which the ring R engages at two opposite points, whereby the rotation of the ring r is prevented, but a different position of the same is made possible when the disk S is turned around with the axes A and α . As can be seen from FIG. 3, the disk S is provided on its periphery with a division into the months and days of the year. The small pointer Z is screwed onto the top of the foot F.

The zenith point of the sun is marked by the small ball K.

The semicircular metal tire C can be easily turned around the globe and is rotatable about the axis a. It is provided with the pointer E , which rests on the equatorial ring r . The latter is divided into 24 parts, corresponding to the number of hours of the day, each of which is marked with a number of hours.

Each of these individual parts can also be divided into minutes and seconds.

The axis a, on which the globe G is rotatably located, is not vertical, but inclined at an angle, corresponding to an angle of 23 Y ₂ degrees at which the earth's orbit intersects the celestial equator.

If you want to determine the time of sunrise for a certain place and day, you turn the disk, S ¹ , until the day in question is under the pointer Z. Then one looks for the place on the globe and marks it with the small disc P, Fig. 6, which can be moved on the semi-circular metal strip C, which can easily be turned around.

Then one turns the globe with the half-hoop C around until the place marked by the plate F is just below the ring R , in such a way that one has the sphere K , which marks the zenith of the sun, on the right hand. The pointer E attached to the tire C will now indicate the exact time of sunrise for the place which is covered by the plate P on the hour ring.

The sunset is determined in such a way that the globe is made only half a turn, whereby the place marked by the plate P comes to stand on the opposite side under the ring R , so that the ball K is now on the left hand . The pointer Z then points

the time of sunset. The time differences can also be found on the equatorial ring read between the different places on the earth's surface.

A second device on the globe can be used for every place, every day and determine the height of the sun every hour.

In the accompanying drawing shows

7 shows this device in its application, FIG. 8 shows a top view of the same,

9 the same seen from the side with an intersection of the outer ring a,

Fig. 10 is a side view of the same and

Fig. II the same seen from below.

Instead of the plate P , which can be displaced on the half-tire C , the double ring consisting of the rings α and b is also attached to it in a displaceable manner. The inner ring b is fixedly rotatably mounted in the outer ring α , as can be seen from the average figure 9. On the ring b rises the quadrant c provided with a degree division. The lever h is mounted on the same ring, movable up and down in hinges, in such a way that it can be moved back and forth in a corresponding recess just above the quadrant c. The small pointer d reaching to the center of the rings is firmly attached to the lower side of the ring α , as are the resilient clips ee, by means of which the double ring is pushed onto the half-hoop C.

The four regions of the sky are marked on the upper side of the outer ring.

The semi-tire C is provided with a division that corresponds to the number of degrees of latitude.

On the small sphere k , which marks the zenith point of the sun, an arrow is attached which is perpendicular to both the vertical and the horizontal axis of the globe, as can be seen in FIG.

If you want to go to a place, e.g. B. Berlin, to determine the height of the sun on May 9 in the morning at 10 o'clock, first the disk 5 (see main drawing) is set so that the date number, here May 9, is under pointer Z. Then one looks for the place on the globe and adjusts the double ring, which is displaceable on the half-hoop C, so that the tip of the pointer d attached to the ring α is exactly above the place, i.e. Berlin here.

On the divided semicircle the pointer d now shows that Berlin is below 53 degrees north latitude.

The globe is then rotated around its axis until the pointer attached to half-hoop C shows the specific hour on the equatorial ring, i.e. 10 o'clock in the morning. After this has happened, the lever h attached to the double ring is set so that it is parallel to the arrow attached to the ball k.

Now you can read from the quadrant how high the sun is at that time stands by the number which indicates the position of the lever on the quadrant, the height shows the position of the sun.

At the same time the position of the quadrant on the ring indicates that the sun is revolving this time is located in a south-easterly direction.

Claims (1)

Patent claim: On globes a device by means of which one can determine exactly the time of sunrise and sunset for every place and every day, as well as the height of the sun for every place and every time, consisting of the axis A stored in the foot F in connection with the Date disc S, the arm H, the axis a, the hour ring r connected to it by the struts s , the half-hoop C with pointer £, the double ring P consisting of the rings α and b with quadrant c and lever h, which forms the zenith of the sun markirenden ball k, the pointer Z and fixedly mounted on the Fufse F rings R. 1 sheet of drawings.